Methods comprising desmopressin

ABSTRACT

The present disclosure is directed to reducing nocturnal voids by administering a dose of desmopressin over a minimum treatment period compared to before administration, and maintaining or improving the reduction of nocturnal voids over the minimum treatment period.

This application is a continuation of U.S. patent application Ser. No.12/732,161 filed Mar. 25, 2010, which is a continuation-in-part of U.S.application Ser. No. 12/469,801, filed May 21, 2009, which claims thebenefit of U.S. Provisional Application No. 61/055,120, filed May 21,2008, the disclosures of which are incorporated herein by reference intheir entireties.

Only recently has nocturia been recognized as a clinical entity in itsown right as opposed to one of many symptoms comprising various lowerurinary tract conditions. It is currently defined by the InternationalContinence Society (ICS) as the complaint that the individual has towake up at night one or more times to void. This applies to any numberof voids at any time during the night provided the person is awakebefore voiding. (1) In general, the term nocturia refers to urination atnight, especially when excessive. It is also referred to as “nycturia.”

There are three broad categories of pathophysiology which account fornocturia: global polyuria; bladder storage problems; and nocturnalpolyuria. (2)

Global polyuria is defined as urine output >40 ml/kg body weight duringa 24 hour period. Causes of polyuria include diabetes mellitus, diabetesinsipidus, and primary thirst disorders.

Bladder storage problems are characterized by frequent voids with smallurine volumes. Causes of bladder storage problems include detrusor overactivity (neurogenic and non-neurogenic); bladder hypersensitivity;bladder outlet obstruction; primary bladder pathology such as cystitis,calculi and neoplasia; and urogenital aging. A pattern of frequentwaking and voiding is also characteristic of a primary sleep disturbancewhich should be part of the differential diagnosis in the evaluation ofa patient with nocturia.

Nocturnal polyuria is defined as the production of an abnormally largevolume of urine during sleep. Healthy young adults from 21-35 years ofage excrete approximately 14±4% of their total urine between the hoursof 11 p.m. and 7 a.m. whereas older people excrete an average of 34±15%.(3-4) The ICS currently defines nocturnal polyuria as a nocturnal urinevolume greater than 20-30% of total 24 hour urine volume, depending onage and in the absence of polyuria. (5)

Nocturnal polyuria may be secondary to systemic conditions such ascongestive heart failure, peripheral edema due to venous stasis orlymphostasis, renal or hepatic failure, lifestyle patterns such asexcessive nighttime drinking, and obstructive sleep apnea. Severalstudies suggest that some individuals with nocturia may have a loss ofthe normal circadian rhythmicity of arginine vasopressin (AVP)secretion. (6-12) AVP is the hormone primarily responsible for theregulation of urine production. In healthy adults, there is a diurnalrelease of AVP with peak blood concentrations occurring during the hoursof sleep. (13) Blunting of the nocturnal phase of AVP secretion insubjects with nocturia would provide one plausible physiologicexplanation for increased nocturnal urine production. However, not allpatients with nocturia lack circadian AVP variation, and not allpatients lacking circadian AVP variation have nocturia. (14) There aremultiple physiologic changes in the mechanisms governing water andsodium regulation which can alter the diurnal rhythm of urine excretion.These include age-related declines in renal concentrating ability andplasma renin concentrations. (15)

Estimates of nocturia prevalence vary widely depending on the definitionused, analytical method employed and population and region surveyed.(16-28) Despite these limitations, the literature strongly indicatesthat nocturia is a common and bothersome condition in males and femalesthat increases in both prevalence and severity with age.

One recent large survey, involving more than 19,000 males and femalesage 18 and older in five countries (Canada, Germany, Italy, Sweden, andthe United Kingdom) and utilizing the ICS definition of nocturia (one ormore times per night) showed that nocturia was the most prevalent lowerurinary tract symptom—reported by 48.6% of men and 54.5% of women—andincreased from 34-44% in individuals less than 39 years old to over 70%in those aged 60 years or more. Even with a higher threshold of two ormore voids per night, the nocturia prevalence of 21-24% exceeded that ofany other lower urinary tract symptom. (29)

Older adults often cite nocturia as one of the most bothersome lowerurinary tract symptoms. In a community-based survey of 423 men age 40and older in the UK, 58 (14%) reported nocturia at least twice pernight. And 67% of these reported that it was “at least a bit of aproblem”—the second most bothersome symptom after frequency at least 9times per day (92%), and more bothersome even than nocturnalincontinence (60%). (30) A community-based survey conducted in the USAincluding 720 subjects with nocturia showed that as little as one voidper night was not only bothersome, but negatively affectedhealth-related quality of life and sleep. For respondents with nocturia≥2 times per night, the impact on health related quality of life wassimilar to that of type 2 diabetes and greater than that ofhypertension. (31)

The most pernicious effect of nocturia is not excessive voiding per se,but its impact on sleep quality and subsequent daytime function as aconsequence of sleep disruption. There is a well establishedrelationship between nocturia and sleep quality. A community-based Dutchsurvey of 1485 people age 50 and older reported that 25.3% reporteddisturbed sleep maintenance, for which nocturia was the most frequentcause (67.5%). (32)

Asplund and Aberg investigated the relationship between sleep andnocturia in a sample of 3000 women and found that sleep deteriorated inassociation with increased nighttime voiding. Women with 3 or more voidsper night reported four times more often that they lacked sleep andsuffered from daytime sleepiness. (33)

Insufficient sleep and daytime fatigue have been linked with depression,mood alteration and diminished quality of life. (34-36) Acommunity-based Swedish survey of 203 working individuals with nocturiaand 80 randomly selected controls showed that the group with nocturiahad significantly lower levels of vitality and utility and greaterimpairment of work and activity as a consequence of sleep deprivation.(37)

Nocturia is also associated with an increased incidence of falls duringthe nighttime hours. (38) Falls are a major health problem among olderpersons and are the leading cause of death from injuries in this agegroup. (39) In a study evaluating the risk of falls in ambulatorypatients 65 years of age and older with nocturia, the odds ratio forfalling increased from 1.46 for subjects with one nocturia event to 2.15for subjects reporting more than three nocturia events per night. (40)

Vasopressin is the primary physiologic determinant of free waterexcretion. It increases the water permeability of the luminal membraneof the renal cortical and medullary collecting ducts thereby promotingfree water reabsorption and reducing urine production. As nocturia isthe clinical consequence of excess nocturnal urine production relativeto bladder capacity, reduction of nocturnal urine volume shouldlogically result in fewer nighttime voiding episodes.

Desmopressin is a synthetic analogue of the naturally occurring hormone8-arginine vasopressin, with modifications including deamination of1-cysteine and substitution of L-arginine at position 8 by D-arginine.Desmopressin exhibits a high and specific antidiuretic effect asdisclosed in U.S. Pat. No. 3,497,491. The resulting molecule has anantidiuretic-to-vasopressor ratio 3000-fold greater than vasopressin anda longer duration of action. (41)

Due to the bothersome nature and varied symptoms associated withnocturia, further investigation of desmopressin was warranted. Thoseinvestigations examined the efficacy and safety of desmopressin in broadpopulations. The result was surprising gender, age, and dose effects ofdesmopressin.

SUMMARY

The present disclosure is directed to gender, age, and dose effects ofdesmopressin on reducing nocturnal voids, increasing an initial periodof undisturbed sleep, and/or reducing nocturnal urine volume.

For example, the present disclosure provides a method for increasing aninitial period of undisturbed sleep in a patient in need thereofcomprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin of 10 μg, wherein the dose ismeasured as the free base of desmopressin and the dose taken over atreatment period increases the patient's initial period of undisturbedsleep.

In further embodiments, the present disclosure is directed to a methodfor reducing nocturnal urine volume in a patient in need thereofcomprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin of 10 μg, wherein the dose ismeasured as the free base of desmopressin and the dose taken over atreatment period reduces the patient's nocturnal urine volume.

In still further embodiments, the present disclosure provides a methodfor reducing nocturnal voids in a female patient in need thereofcomprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin of 10 μg or 25 μg, wherein the doseis measured as the free base of desmopressin and the dose taken over atreatment period reduces the patient's nocturnal voids.

In other embodiments, the present disclosure is directed to a method forincreasing an initial period of undisturbed sleep in a female patient inneed thereof comprising: administering to the patient prior to bedtimean orodispersible dose of desmopressin of 10 μg or 25 μg, wherein thedose is measured as the free base of desmopressin and the dose takenover a treatment period increases the patient's initial period ofundisturbed sleep.

In yet further embodiments, the present disclosure provides a method forreducing nocturnal urine volume in a female patient in need thereofcomprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin of 10 μg or 25 μg, wherein the doseis measured as the free base of desmopressin and the dose taken over atreatment period reduces the patient's nocturnal urine volume.

Further for example, the present disclosure is directed to a method forreducing nocturnal voids in a female patient above 50 years of age inneed thereof comprising: administering to the patient prior to bedtimean orodispersible dose of desmopressin of 10 μg or 25 μg, wherein thedose is measured as the free base of desmopressin and the dose takenover a treatment period reduces the patient's nocturnal voids.

In still further embodiments, the present disclosure provides a methodfor increasing an initial period of undisturbed sleep in a femalepatient above 50 years of age in need thereof comprising: administeringto the patient prior to bedtime an orodispersible dose of desmopressinof 10 μg or 25 μg, wherein the dose is measured as the free base ofdesmopressin and the dose taken over a treatment period increases thepatient's initial period of undisturbed sleep.

In yet further embodiments, the present disclosure is directed to amethod for reducing nocturnal urine volume in a female patient above 50years of age in need thereof comprising: administering to the patientprior to bedtime an orodispersible dose of desmopressin of 10 μg or 25μg, wherein the dose is measured as the free base of desmopressin andthe dose taken over a treatment period reduces the patient's nocturnalurine volume.

In other useful embodiments, the present disclosure provides a methodfor reducing nocturnal voids in a female patient above 65 years of agein need thereof comprising: administering to the patient prior tobedtime an orodispersible dose of desmopressin of 25 μg, wherein thedose is measured as the free base of desmopressin and the dose takenover a treatment period reduces the patient's nocturnal voids.

In further useful embodiments, the present disclosure is directed to amethod for increasing an initial period of undisturbed sleep in a femalepatient above 65 years of age in need thereof comprising: administeringto the patient prior to bedtime an orodispersible dose of desmopressinof 25 μg, wherein the dose is measured as the free base of desmopressinand the dose taken over a treatment period increases the patient'sinitial period of undisturbed sleep.

In particular embodiments, the present disclosure provides a method forreducing nocturnal urine volume in a female patient above 65 years ofage in need thereof comprising: administering to the patient prior tobedtime an orodispersible dose of desmopressin of 25 μg, wherein thedose is measured as the free base of desmopressin and the dose takenover a treatment period reduces the patient's nocturnal urine volume.

In some embodiments, the present disclosure is directed to a method forreducing nocturnal urine volume in a male patient in need thereofcomprising: measuring the patient's serum sodium level; administering tothe patient, with a serum sodium level of at least 130 mmol/L, prior tobedtime an orodispersible dose of desmopressin of 100 μg, wherein thedose is measured as the free base of desmopressin; measuring thepatient's serum sodium level at a time interval after administration;continuing the administration of the dose of desmopressin with thepatient having at least 130 mmol/L serum sodium level; wherein the doseadministered over a treatment period reduces the patient's nocturnalurine volume.

In another embodiment, the disclosure provides a method of treatingnocturia by administering to a subject in need thereof a sublingualdaily dose of about 10 μg, 25 μg, 50 μg, or 100 μg desmopressin(measured as the free base). The subject to be treated has an average ofa least 0.5 fewer nocturnal urinary voids per night after 28 days oftreatment with desmopressin.

In a further embodiment, the present disclosure is directed to a methodfor reducing nocturnal voids in a patient in need thereof comprising:administering to the patient prior to bedtime an orodispersible dose ofdesmopressin ranging from 25 μg to 100 μg, wherein the dose is measuredas the free base of desmopressin and the dose taken over a minimumtreatment period reduces the patient's nocturnal voids compared to thepatient's nocturnal voids before administration of the dose.

In still yet another embodiment, the present disclosure provides for amethod for improving a reduction in nocturnal voids in a patient in needthereof comprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin ranging from 25 μg to 100 μg,wherein the dose is measured as the free base of desmopressin and thedose taken over a minimum treatment period reduces the patient'snocturnal voids compared to before administration and improves thereduction in nocturnal voids over the duration of the minimum treatmentperiod.

In a further embodiment, the present disclosure provides for a methodfor maintaining a reduction in nocturnal voids in a patient in needthereof comprising: administering to the patient prior to bedtime anorodispersible dose of desmopressin of ranging from 25 μg to 100 μg,wherein the dose is measured as the free base of desmopressin and thedose is taken over a minimum treatment period reduces the patient'snocturnal voids compared to the patient's nocturnal voids beforeadministration of the dose.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 graphically illustrates the weekly change from baseline in meannumber of nocturnal voids along with the corresponding p-values.

FIG. 2 graphically illustrates the mean observed and predicted change innocturnal voids by gender and dose.

FIG. 3 graphically illustrates the decrease in total and nocturnal urinevolume for the placebo, 10 μg, 25 μg, 50 μg, and 100 μg groups.

FIG. 4 graphically illustrates the mean observed and predicted change innocturnal urine by gender and dose.

DESCRIPTION

Particular aspects of the disclosure are described in greater detailbelow. The terms and definitions as used in the present application andas clarified herein are intended to represent the meaning within thepresent disclosure. The patent and scientific literature referred toherein and referenced above are hereby incorporated by reference. Theterms and definitions provided herein control, if in conflict with termsand/or definitions incorporated by reference.

Terms and Definitions

The singular forms “a,” “an,” and “the” include plural reference unlessthe context dictates otherwise.

The terms “approximately” and “about” mean to be nearly the same as areferenced number or value. As used herein, the terms “approximately”and “about” should be generally understood to encompass ±10% of aspecified amount, frequency or value. With regard to specific values, itshould be understood that specific values described herein for subjectpopulations (e.g., the subject of the described clinical trial)represent median values, unless otherwise indicated as, e.g., meanvalues. Accordingly, aspects of the present disclosure requiring aparticular value in a subject are substantially supported herein bypopulation data in which the relevant value is assessed to be ameaningful delimitation of the subject population.

As used herein, the term “first sleep period” refers to the time elapsedfrom bedtime to either first void or morning arising.

The term “hyponatraemia” as used herein refers to a serum sodium valuebelow the lower limit of the normal reference range, for example, aserum sodium level <130 mmol/L.

The term “nocturnal enuresis” as used herein refers to a condition inwhich a person who has bladder control while awake urinates whileasleep.

As used herein, the term “nocturnal polyuria” refers to an increasednocturnal output of urine. For example, a ratio of nighttime urinevolume over the 24-hour urine volume to be equal to or greater than 33%.

As used herein, the term “nocturnal urine” refers to the total urinevolume from 5 minutes after bedtime until rising in the morning,including the first void within 30 minutes of rising.

The term “nocturnal void” as used herein refers to a void occurring from5 minutes after bedtime until rising in the morning with the intentionof getting up.

The term “nocturia” refers to the complaint that an individual has towake up at night one or more times to void.

The term “overactive bladder” as used herein refers to urgency, with orwithout urge incontinence, usually accompanied by frequency andnocturia.

The term “polydipsia” as used herein refers to excessive fluidconsumption.

The term “urine osmolaity” as used herein refers to the concentration ofelectrolytes in urine.

The term “uroflometry” as used herein refers to a measurement of therate of urine expelled from the bladder during bladder emptying. Flowrate is measured as mL/sec voided.

The terms “administer,” “administration” or “administering” as usedherein refer to (1) providing, giving, dosing and/or prescribing byeither a health practitioner or his authorized agent or under hisdirection desmopressin, and (2) putting into, taking or consuming by thepatient or person himself or herself, desmopressin.

LIST OF ABBREVIATIONS

Abbreviations Meaning of Abbreviations in Document

AE Adverse Event

ITT Intention-To-Treat

LOCF Last-Observation-Carried-Forward

MED Minimum Effective Dose

OC Observed Cases

PP Per Protocol

SD Standard Deviation

SAE Serious Adverse Event

NQoL Nocturia Quality of Life Questionnaire

PSQI Pittsburgh Sleep Quality Index

SF Short Form

μg Microgram

WebEZ Web Based Centralized Patient Randomization System

Melt Formulation

Desmopressin Melt tablets contain desmopressin acetate in a freeze-driedpresentation formulated with fish gelatin, mannitol and citric acid. Theresulting oral lyophilisate disintegrates instantaneously in the mouthwithout the need for water. An orodispersible pharmaceutical dosage formof desmopressin with good bioavailability is described in U.S. patentapplication Ser. No. 10/513,437 (U.S. Pub. No. 2005/0232997 A1), thecontents of which are incorporated herein in their entirety. The Meltdosage form is preferably provided as a desmopressin acetate salt. Thedesmopressin dosage may be expressed as free base, even though thedesmopressin is actually supplied as the acetate salt. Except whereotherwise indicated, the doses utilized in the present methodscorrespond to desmopressin free base even though the dosage form is adesmopressin acetate. Therefore, the 100 μg dose of desmopressindescribed herein is 100 μg of desmopressin free base, which correspondsto a proportionately higher weight value of desmopressin acetate(approximately 112.4 μg of desmopressin acetate for a desmopressin Meltpreparation that is 89% w/w of desmopressin free base and for which thebalance of 11% w/w is acetate, water and impurities). Similarly, the 50μg, 25 μg, and 10 μg dosages all represent the weights of desmopressinfree base, with the corresponding weights of desmopressin acetate beingproportionately higher. Accordingly, 0.1 mg of desmopressin acetate isequivalent to about 89 μg of desmopressin free base.

The relative bioavailability between the tablet and melt formulationswas investigated in an open-label, randomized crossover study in which28 healthy subjects were administered 240 μg melt and 0.4 mg tablet(given as 2×0.2 mg tablets) separated by seven days. AUC, C_(max),T_(max) and t_(1/2) were similar, indicating that 0.1 mg tablet resultsin exposure similar to that of a 60 μg melt (equivalent to 67 μg ofdesmopressin acetate).

Example: Clinical Study

Objectives

The primary objectives of Part I of this study (28-day efficacy) were:(1) to demonstrate the superiority of one or more doses of the Meltformulation of desmopressin to placebo in reducing the mean number ofnocturnal voids in a broad population of adult patients with nocturiaafter 28 days of treatment; (2) to demonstrate the superiority of one ormore doses of the Melt formulation of desmopressin to placebo in theproportion of subjects with >33% reduction from baseline in mean numberof nocturnal voids after 28 days of treatment; and (3) treatment safety.

The primary objectives of Part II of this study (extension study) were:(1) to demonstrate the durability of effect achieved in Part I of one ormore doses of desmopressin Melt; and (2) treatment safety.

The secondary objective of both Parts I and II was: to compare theeffect of several doses of desmopressin Melt to placebo o sleepdisturbance and quality of life.

Overall Study Design

This was a 2-part (Parts I and II), randomized, double-blind,placebo-controlled, parallel-group, multicenter study to investigate theefficacy and safety of 4 doses of a fast-dissolving (“Melt”) formulationof desmopressin for the treatment of nocturia in adults. All treatmentswere administered orally once per night approximately 1 hour prior tobedtime; subjects were instructed to limit their fluid intake prior todrug self-administration. In Part I, subjects were randomly assigned to1 of 5 treatment groups: placebo or desmopressin Melt 10 μg, 25 μg, 50μg, or 100 μg. Randomization was to be stratified by age (<65, ≥65years) and by the absence/presence of nocturnal polyuria, defined as aratio of nighttime urine volume/24-hour urine volume ≥33%. To achievethe desired number of subjects within each stratum, enrollment ofsubjects in a particular stratum (age and/or presence/absence ofnocturnal polyuria) could be halted. If this was necessary, allinvestigative sites were to be informed in writing at least 1 week inadvance to stop screening in a population of subjects.

A total of 750 subjects were planned to be enrolled, with approximately150 subjects per treatment group. Part I of the study was conducted in 7visits. Screening (Visit 1) occurred within 21 days of dosing (Day 1,Visit 2); subjects returned for follow-up visits on Days 4, 8, 15, 22,and 28 (end of Part I). Duration of treatment in Part I was 28 days.

Immediately upon completion of Part I of the study, all subjects onactive treatment continued into Part II on the same treatment forapproximately 1 to 6 months. Subjects assigned to placebo in Part I wererandomly assigned to 1 of the 4 active treatments in Part II. To ensurethat the study remained fully blinded during the full extent of bothParts I and II, re-randomization of subjects assigned to placebo after 4weeks of treatment was predetermined at the time of initialrandomization.

Subjects began Part II at the Final Visit for Part I (Day 28) andreturned for follow-up visits on Days 4, 8, 15, 29, and every 4 weeksthereafter until the database was locked for Part I and the treatmentgroups were unblinded. The total treatment duration for each subjectdepended on when that subject was randomized in Part I and was estimatedto be a minimum of 4 weeks and a maximum of 6 months.

Upon completion of Part II of the study, subjects were given the optionto participate in an open-label study with expected total treatmentduration (double-blind extension plus open-label study) of at least 12months (i.e., Part III). In Part III, subjects were assigned to the sametreatment as in Part II, initially in a blinded manner. Subjects wereunblinded and the study became open label only when all subjects inParts I and II remaining in the study had entered Part III. During PartIII, 10 μg was identified as a sub-therapeutic dose based on efficacydata from Part I. As a consequence, patients in the 10 μg treatmentgroup were re-randomized (beginning Q4 2008) to one of the othertreatment groups (i.e., 25 μg, 50 μg, or 100 μg). The total treatmentduration was at least 12 months.

A total of 508 patients entered the open-labeled extension (i.e., PartIII). In total, 367 patients had ≥1 year of treatment.

Selection of Doses in Study

A previous clinical program investigating the efficacy and safety of aTablet formulation of desmopressin for nocturia utilized doses of 100μg, 200 μg, and 400 μg. All 3 doses demonstrated a clear effect onpharmacodynamic and clinical endpoints. Although the use of adose-titration scheme limits the interpretation of dose response, doseshigher than 100 μg offered only a marginal improvement in efficacy.

The dose relationship between the Tablet and Melt formulations wasinvestigated in an open-label, randomized crossover study in which 28healthy subjects were administered 240 μg Melt and 400 μg Tablet (givenas 2×200 μg Tablets) separated by 7 days. AUC, C_(max), T_(max), andt_(1/2) were similar, indicating that 100 μg Tablet provides an exposuresimilar to that of 60 μg Melt.

The present study investigated dose levels substantially lower thanthose used in the Tablet study. While there are no data with the Meltformulation in the target population to guide dose selection for dosesbelow 100 μg tablet/60 μg Melt, pharmacokinetic (PK) and pharmacodynamic(PD) studies have been conducted in water-loaded healthy subjects andwater-loaded children 6 to 12 years of age with nocturnal enuresis.Based on data from these 2 studies, a model simulating PK and PD hasbeen developed. If antidiuretic activity is defined in terms of durationof urine osmolality greater than 200 mOsm/kg, the model indicates that adose of 10 μg Melt may potentially be subtherapeutic and doses of 25 μgto 100 μg should provide 2.75 to 8.5 hours of antidiuretic activity.

Selection of Study Population: Inclusion Criteria

Subjects who met the following inclusion criteria were eligible for thestudy: provided written informed consent prior to the performance of anystudy-related activity, defined as any procedure that would not havebeen performed during the normal management of the subject; and was amale or female subject, 18 years of age and older, with an average of ≥2nocturnal voids per night determined via a 3-day frequency-volume chartduring the screening period

Exclusion Criteria

The presence of any of the following excluded a subject from studyenrollment:

Genitourinary Tract Conditions

Males:

Clinical suspicion of bladder outlet obstruction and/or urine flow <5mL/sec. If medical history and/or physical examination suggested bladderoutlet obstruction, uroflowmetry was to be performed to confirm thediagnosis.

Surgical treatment, including transurethral ablative treatments, forbladder outlet obstruction/benign prostatic hyperplasia (BPH) performedwithin the past 6 months.

Females:

Pregnancy; females of reproductive age were to document they were usinga reliable method of contraception.

Use of pessary for pelvic prolapse.

Presence of unexplained pelvic mass.

Males and Females:

Clinical suspicion of urinary retention and/or post-void residualvolume >150 mL; if medical history and/or physical examination suggestedurinary retention, bladder ultrasound or catheterization was to beperformed to confirm the diagnosis.

Current or past urologic malignancies (e.g., bladder cancer, prostatecancer).

Clinical evidence of current genitourinary tract pathology that couldinterfere with voiding.

History of neurogenic detrusor activity (previously known as detrusorhyperreflexia).

Systemic Medical Conditions

Suspicion or evidence of cardiac failure.

Uncontrolled hypertension.

Uncontrolled diabetes mellitus.

Renal insufficiency; serum creatinine was to be within normal limits andestimated glomerular filtration rate (eGFR) was to be ≥60 mL/min.

Hepatic and/or biliary disease; aspartate transaminase (AST) and/oralanine transaminase (ALT) were not to be >2×upper limit of normal (ULN)and total bilirubin was not to be >1.5 mg/dL.

Hyponatraemia; serum sodium level was to be within normal limits asdefined by the Sponsor and central laboratory.

Diabetes insipidus (urine output >40 mL/kg over 24 hours).

Syndrome of inappropriate antidiuretic hormone secretion (SIADH).

Psychogenic or habitual polydipsia.

Obstructive sleep apnea requiring therapy.

Other

Known alcohol or substance abuse.

Work or lifestyle that potentially interfered with regular nighttimesleep (e.g., shift workers).

Previous desmopressin treatment for nocturia.

Any other medical condition, laboratory abnormality, psychiatriccondition, mental incapacity, or language barrier that, in the judgmentof the Investigator, rendered the subject unsuitable for a clinicaltrial or impaired subject participation in the study.

Use of loop diuretics (furosemide, torsemide, ethacrynic acid). Otherclasses of diuretics (thiazides, triamterene, chlorthalidone, amiloride,indapamide) were permitted, either as monotherapy or combinationtherapy. Subjects using a diuretic were to be encouraged to take it inthe morning, if medically feasible.

Use of any other investigational drug within 30 days of screening.

Discontinuation Criteria

Any subject with a serum sodium value of 125 mmol/L or less at any pointduring the study was to be withdrawn immediately and further evaluatedand treated as necessary.

Subjects had the right to withdraw from the study at any time for anyreason without providing justification. However, the Investigator was totake appropriate steps to ensure that withdrawal was accomplished in asafe manner. A subject could also be discontinued at the discretion ofthe Investigator or Sponsor because of safety concerns or if judgednoncompliant with the study procedures to an extent that could affectthe study results. The Investigator and the Sponsor were to agree onsubject discontinuation prior to withdrawal, and unnecessary withdrawalof subjects was to be avoided.

Subjects discontinued from the study were to be scheduled for anEnd-of-Study (EoS) assessment as soon as possible after the decision towithdraw the subject had been made. For any discontinuation, theInvestigator was to obtain all the required data and document the dateof the premature withdrawal and the main reason in the electronic casereport form (eCRF). If the reason for withdrawal was an adverse event(AE), the specific event or laboratory abnormality was to be recorded inthe eCRF. The Investigator was to make a thorough effort to document theoutcome. Discontinued subjects were not replaced.

Treatments Administered

Study drug was administered as an orally disintegrating tablet ofdesmopressin (desmopressin Melt) or placebo.

Subjects were randomly assigned to 1 of 5 fixed-dose treatment groups inPart I: placebo or desmopressin Melt 10 μg, 25 μg, 50 μg, or 100 μg. Alltreatments were administered orally once per night approximately 1 hourprior to bedtime. Subjects were instructed to place the tablet undertheir tongue, without water. Subjects were provided with sufficientstudy drug for the duration of Part I.

Study Endpoints

The primary endpoints for efficacy assessment were: (1) change in meannumber of nocturnal voids from baseline evaluation to final visit (Day28); and (2) proportion of subjects with >33% reduction in the meannumber of nocturnal voids from baseline to final visit (Day 28). Afurther description and corresponding data directed to the secondprimary endpoint (i.e., portion of subjects with >33% reduction in themean number of nocturnal voids) are not provided herein.

The secondary efficacy endpoints were: (1) durability of effect achievedin Part I; (2) change in initial period of undisturbed sleep, defined asthe elapsed time in minutes from going to bed with the intention ofsleeping to the time of awakening for the first nocturnal void; and (3)change in duration of total sleep time. Additional secondary endpointswere collected, e.g., change in nocturia-specific quality of life asassessed by scores on the International Consultation on IncontinenceModular Questionnaire—Noctuira and the Noctuira Quality of LifeQuestionnaire, change in quality of sleep as assessed by the globalscore of the Pittsburgh Sleep Quality Index, and change in overallquality of life as assessed by the short form-12v2. A description of theadditional secondary efficacy endpoints and their accompanying data arenot provided herein.

Changes in urine volume from baseline to the end of Day 28 were alsoassessed and included herein.

Flow Chart

A study flow chart, showing study assessments and procedures conductedat each study visit, are presented in Table 1 for Part I.

TABLE 1 Study flow chart for Part I. Visit (screening) 1 (randomization)2 3 4 5 6 7 (EoS)^(a) Week ≤21 days 1 2 3 4 Procedure of Visit 2 1 4 815 ± 3 22 ± 3 28 ± 3 Informed consent X^(b) Inclusion/exclusion criteriaX Login to WebEZ for Subject ID X number Demographic/medical history XBody weight X X Height X Physical examination X X Vital signs (BP,pulse) X X X X X X X Concomitant medications X X X X X X X Labs:chemistry (including serum X X sodium), hematology, urinalysis Urineosmolality^(c) (exploratory) X Urine pregnancy test X X Uroflometry(males only)^(d) X Assess post void residual volume^(d) X Dispensesleep/voiding diary (3 X X days)^(e) Actigraphy^(f) X X Adverse events XX X X X X Review voiding and/or sleep diary X X X X X Nocturiaquestionnaires: ICIQ-N, X X PSQI, NQoL, SF-12v2 Randomization via WebEZX Dispense voiding diary (3 days)^(e) X X X Serum sodium X X X X Studydrug accountability X X X X X Dispense study drug for Part II (kit Xnumber assigned via WebEZ) EoS = End of Study; WebEZ = web-basedcentralized patient randomization system; BP = blood pressure; ICIQ-N =International Consultation on Incontinence questionnaire - Nocturia;PSQI = Pittsburgh Sleep Quality Index; NQoL = Nocturia Quality of Life;SF-12v2 = Short Form-12, version 2 ^(a)Discontinued subjects were tocomplete an End-of-Study Visit as soon as possible after studydiscontinuation. ^(b)Written informed consent was to be obtained priorto any study-related procedures. ^(c)Collection of first night-timeurine void prior to randomization visit. ^(d)Uroflometry was collectedin males only if there was suspicion of obstruction; post residual urinevolume was measured using an ultrasound only if there was clinicalsuspicion of urinary retention. ^(e)Voiding diaries were completed for 3consecutive 24-hour cycles; diaries for Weeks 1, 2, and 3 only requiredthe “wake time” of the night-time void. ^(f)Actigraphy was used in asubset of subjects (at 6 study sites).

Disposition of Subjects

A total of 1412 subjects were screened for Part I of the study; 613subjects were screening failures and 799 subjects were randomized totreatment. The most common recorded reasons for screening failure wererenal insufficiency (15%) and not averaging ≥2 nocturnal voids over the3-day screening period (10%). A total of 710 (89%) subjects completedPart I of the study and 89 (11%) subjects prematurely discontinued.Across treatment groups, 6% to 16% of subjects prematurely discontinued.The most common reasons for discontinuation overall were withdrawal ofconsent (4%), adverse event (2%), and lost to follow-up (2%).

Data Sets Analyzed

Of the 799 randomized subjects in Part I, 757 subjects who received atleast 1 dose of study drug and had follow-up data were included in theintent to treat (ITT) analysis dataset. Overall, 10% of ITT subjects hada major protocol violation and were excluded from the per-protocol (PP)analysis dataset. Of the 682 PP subjects, 10% did not have bothscreening and final visit data on number of nocturnal voids and wereexcluded from the observed cases (OC) analysis dataset. All 799randomized subjects received at least 1 dose of study drug (desmopressinor placebo) and had at least 1 safety assessment and, therefore, wereincluded in the safety analysis dataset.

Primary Efficacy Endpoint

Number of Nocturnal Voids

The mean number of nocturnal voids decreased from baseline to Day 28 inall treatment groups, with greater decreases observed with increasingdose of desmopressin. The reduction in mean number of nocturnal voids,compared to placebo, was statistically significant for the 100 μg(p<0.0001) and 50 μg (p=0.0207) groups.

The trend of greater decreases in mean number of nocturnal voids withincreasing dose of desmopressin was evident in subjects stratified byage (<65 years, ≥65 years) and in subjects with nocturnal polyuria. Toofew subjects (13 to 18 subjects per treatment group) did not havenocturnal polyuria to make meaningful comparisons. The reduction in meannumber of nocturnal voids, compared to placebo, was statisticallysignificant for the 100 μg group for all 4 stratification factors andfor the 50 μg group for subjects with nocturnal polyuria.

A summary of changes from baseline to the final visit in the number ofnocturnal voids is presented for all groups (ITT population) in Table 2.

TABLE 2 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for all groups. Dose n mean stddevstderr min median max Placebo 156 −0.86 1.05 0.08 −4.00 −0.83 1.67 10 ug155 −0.83 1.07 0.09 −4.33 −0.67 2.33 25 ug 152 −1.00 1.13 0.09 −3.67−1.00 2.33 50 ug 148 −1.18 1.19 0.10 −5.00 −1.00 2.00 100 ug  146 −1.431.22 0.10 −5.00 −1.33 4.33 Total 757 −1.05 1.15 0.04 −5.00 −1.00 4.33n—population size; stddev—standard deviation; stderr—standard error;min—minimum; and max—maximum

Mean decreases in the number of nocturnal voids were observed by Day 8,with a trend for greater decreases with increasing desmopressin doses;these findings continued at Day 15 and Day 22. Notably, compared toplacebo, statistically significant differences were observed for the 25μg, 50 μg, and 100 μg doses on Day 8 and Day 15 of treatment, withsignificant differences for the 2 higher doses also on Day 22 and Day28. Weekly change from baseline in mean number of nocturnal voids, alongwith p-values for each desmopressin Melt dose compared to placebo, isdisplayed in FIG. 1.

Among females, the reduction in mean number of nocturnal voids, comparedto placebo, was statistically significant for the 100 μg (p<0.0001), 50μg (p=0.0091), and 25 μg (p=0.0200) groups. Thus, among females,efficacy was demonstrated for the primary endpoint of nocturnal voidsfor all but the lowest dose of desmopressin.

A summary of changes from baseline to the final visit in the number ofnocturnal voids is presented for all females, females over 50 years ofage, and females over 65 years of age (ITT population) in Tables 3, 4and 5.

TABLE 3 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for all females. Dose n mean stddevstderr min median max Placebo 66 −0.88 1.01 0.12 −3.33 −0.67 1.00 10 ug73 −1.15 1.07 0.13 −4.33 −1.00 1.00 25 ug 65 −1.22 1.06 0.13 −3.33 −1.331.00 50 ug 71 −1.23 1.06 0.13 −4.00 −1.00 2.00 100 ug  66 −1.51 1.140.14 −5.00 −1.33 1.00 Total 341 −1.20 1.08 0.06 −5.00 −1.00 2.00n—population size; stddev—standard deviation; stderr—standard error;min—minimum; and max—maximum

Although not statistically significant for the 10 μg group butstatistically significant for the 25 μg group, there was a decreaseobserved in the median number of nocturnal voids identified in Table 3for all females. For example, the 10 μg and 25 μg groups exhibited atleast 1.0 fewer nocturnal urinary voids per night on desmopressiontreatment compared to baseline before treatment. The placebo exhibitedonly 0.67 fewer nocturnal urinary voids per night compared to baseline.

TABLE 4 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for females over 50 years of age. Dosen mean stddev stderr min median max Placebo 45 −0.74 0.93 0.14 −2.67−0.67 1.00 10 ug 51 −1.08 1.04 0.15 −4.33 −1.00 0.33 25 ug 49 −1.35 1.040.15 −3.33 −1.33 1.00 50 ug 55 −1.15 1.13 0.15 −4.00 −1.00 2.00 100 ug 48 −1.44 1.24 0.18 −5.00 −1.33 1.00 Total 248 −1.16 1.10 0.07 −5.00−1.00 2.00 n—population size; stddev—standard deviation; stderr—standarderror; min—minimum; and max—maximum

Although not statistically significant for the 10 μg group butstatistically significant for the 25 μg group, there was a decreaseobserved in the median number of nocturnal voids identified in Table 4for females over 50 years of age. For example, the 10 μg and 25 μggroups exhibited at least 1.0 fewer nocturnal urinary voids per night ondesmopression treatment compared to baseline before treatment. Theplacebo exhibited only 0.67 fewer nocturnal urinary voids per nightcompared to baseline.

TABLE 5 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for females over 65 years of age. Dosen mean stddev stderr min median max Placebo 21 −0.51 0.73 0.16 −2.33−0.33 0.67 10 ug 25 −0.93 1.07 0.21 −4.33 −0.67 0.33 25 ug 22 −1.27 0.990.21 −2.67 −1.67 1.00 50 ug 20 −0.97 0.95 0.21 −2.33 −1.00 1.33 100 ug 25 −1.00 1.18 0.24 −3.00 −1.00 1.00 Total 113 −0.94 1.02 0.10 −4.33−1.00 1.33 n—population size; stddev—standard deviation; stderr—standarderror; min—minimum; and max—maximum

Similarly to the other female groups, there was a decrease observed inthe median number of nocturnal voids identified in Table 5 for femalesover 65 years of age at the 25 μg group. For example, the 25 μg groupexhibited at least 1.67 fewer nocturnal urinary voids per night ondesmopressin treatment compared to baseline before treatment. Theplacebo exhibited only 0.33 fewer nocturnal urinary voids per nightcompared to baseline.

Among males, statistically significant differences from placebo wereobserved for the 100 μg group in the reduction in mean number ofnocturnal voids (p=0.0049).

A summary of the changes from baseline to the final visit in the numberof nocturnal voids is presented for all males and all males withmonitoring (ITT population) in Tables 6 and 7.

TABLE 6 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for all males. Dose n mean stddevstderr min median max Placebo 90 −0.84 1.09 0.12 −4.00 −1.00 1.67 10 ug82 −0.54 0.99 0.11 −3.00 −0.67 2.33 25 ug 87 −0.83 1.15 0.12 −3.67 −0.672.33 50 ug 77 −1.13 1.30 0.15 −5.00 −1.00 1.33 100 ug  80 −1.38 1.280.14 −4.33 −1.33 4.33 Total 416 −0.94 1.19 0.06 −5.00 −1.00 4.33n—population size; stddev—standard deviation; stderr—standard error;min—minimum; and max—maximum

TABLE 7 Change from baseline to final visit (Day 28) of nocturnal voids(ITT analysis dataset in Part I) for all males with monitoring. Dose nmean stddev stderr min median max Placebo 74 −0.88 1.15 0.13 −4.00 −1.001.67 10 ug 66 −0.66 0.97 0.12 −3.00 −0.67 1.33 25 ug 72 −0.91 1.16 0.14−3.67 −0.67 2.33 50 ug 52 −1.09 1.26 0.17 −5.00 −1.00 1.33 100 ug  60−1.41 1.35 0.17 −4.33 −1.67 4.33 Total 324 −0.97 1.19 0.07 −5.00 −1.004.33 n—population size; stddev—standard deviation; stderr—standarderror; min—minimum; and max—maximum

The differences among males and females in the change in number ofnocturnal voids is illustrated in FIG. 2. In FIG. 2, the mean observed(full line) and predicted (broken line) change in number of voids bygender and dose demonstrate that the 10 μg and 25 μg groups for femalesexhibit a larger decrease in nocturnal voids compared to the 10 μg and25 μg groups for males. The side-by-side comparison in FIG. 2 highlightsthe gender and dose differences without the requirement of statisticalsignificance.

Based on these gender differences, the minimum effective dose (MED) forfemales is 25 μg and the MED for males is 100 μg.

Long Term Data—Nocturnal Voids

At one year (Part III), the mean decrease in nocturnal voids per nightwas 1.4, 1.77, and 2.11 (for 25 μg, 50 μg, and 100 μg, respectively)based on all eligible subjects. The mean decreases in nocturnal voidsdemonstrate that the decrease observed for the respective concentrationsat Day 28 (i.e., Part I) are maintained over a longer treatment period(e.g., 52 weeks) and in some instances, are be even improved. A summaryof the changes from baseline is presented for all eligible subjects.With respect to this particular data for Part III, “all eligiblesubjects” means those subjects that continued through Parts I, II, andIII of the study on the same dose (i.e., re-randomized placebo subjectshave been excluded) and completed the 1 year diary.

Applicants note that statistical significance cannot be demonstrated forthe Part III data on nocturnal voids, as the placebo group was notmaintained for Part III. However, based on the data below, theadditional decreases in the number of voids can be characterized asclinically significant. As used here, “clinically significant” means aminimum worthwhile effect.

A summary of changes from baseline to day 28 and to week 52 in thenumber of nocturnal voids is present for all eligible groups in TablesA, B, and C for the 25 μg, 50 μg, and 100 μg doses of desmopressin.

TABLE A Baseline at day 0 and changes from baseline nocturnal voids forall eligible subjects at the 25 μg dosage. n Mean Std Dev Min Max Day 086 3.24 1.27 2.00 8.67 Day 28 86 −0.98 1.15 −3.33 2.33 Week 8 67 −1.161.13 −3.33 2.67 Week 12 57 −1.29 1.14 −3.00 1.33 Week 20 42 −1.48 1.05−3.67 1.67 Week 28 67 −1.44 1.20 −4.33 1.00 Week 52 86 −1.41 1.26 −4.672.33 n—population size; stddev—standard deviation; min—minimum; andmax—maximum

TABLE B Baseline at day 0 and changes from baseline for all eligiblesubjects at the 50 μg dosage. n Mean Std Dev Min Max Day 0 76 3.42 1.082.00 7.00 Day 28 76 −1.22 1.20 −5.00 2.00 Week 8 58 −1.44 1.05 −4.001.33 Week 12 51 −1.44 1.09 −3.67 1.00 Week 20 48 −1.80 1.12 −4.00 1.00Week 28 44 −1.55 1.21 −5.00 1.00 Week 52 76 −1.80 1.31 −6.67 0.33n—population size; stddev—standard deviation; min—minimum; andmax—maximum

TABLE C Baseline at day 0 and changes from baseline for all eligiblesubjects at the 100 μg dosage. n Mean Std Dev Min Max Day 0 73 3.30 1.112.00 7.00 Day 28 73 −1.406 1.26 −5.00 4.33 Week 8 62 −1.61 1.11 −5.000.67 Week 12 46 −1.83 1.12 −5.00 0.33 Week 20 43 −1.95 1.12 −5.33 0 Week28 47 −1.83 0.86 −4.67 −0.33 Week 52 73 −2.11 1.14 −6.33 0.67n—population size; stddev—standard deviation; min—minimum; andmax—maximum

Although not statistically significant, the change from baseline to Week52 in comparison to the change of baseline to day 28 demonstrates thatfor all eligible subjects, the decrease in frequency of nocturnal voidscan be maintained and/or improved over a longer treatment period in aclinically significant manner.

Among females, the reduction in mean number of nocturnal voids frombaseline to week 52 maintained or improved, particularly at the 25 μgdose. A summary of changes from baseline to week 52 in the number ofnocturnal voids is presented for all females in Tables D-F for the 25μg, 50 μg, and 100 μg doses of desmopressin.

TABLE D Baseline at day 0 and changes from baseline for all eligiblefemale subjects at the 25 μg dosage. n Mean Std Dev Min Max Day 0 383.23 1.31 2.00 8.67 Day 28 38 −1.26 1.06 −3.33 0.67 Week 8 32 −1.51 0.83−3.00 0 Week 12 29 −1.66 0.98 −3.00 0.67 Week 20 22 −1.68 0.96 −3.000.67 Week 28 27 −1.86 1.18 −4.33 0.33 Week 52 38 −1.75 1.16 −4.67 2.00n—population size; stddev—standard deviation; min—minimum; andmax—maximum

TABLE E Baseline at day 0 and changes from baseline of nocturnal voidsfor all eligible female subjects at the 50 μg dosage. n Mean Std Dev MinMax Day 0 31 3.17 0.70 2.00 4.67 Day 28 31 −1.30 1.16 −4.00 2.00 Week 826 −1.60 1.045 −4.00 1.00 Week 12 23 −1.62 1.072 −3.33 0.67 Week 20 18−1.93 1.11 −3.67 0.33 Week 28 19 −1.89 0.88 −3.33 0 Week 52 31 −1.950.77 −3.67 −0.33 n—population size; stddev—standard deviation;min—minimum; and max—maximum

TABLE F Baseline at day 0 and changes from baseline of nocturnal voidsfor all eligible female subjects at the 100 μg dosage. n Mean Std DevMin Max Day 0 37 3.08 1.12 2.00 7.00 Day 28 37 −1.50 1.22 −5.00 1.00Week 8 32 −1.69 1.27 −5.00 0.33 Week 12 27 −1.79 1.23 −5.00 0.33 Week 2022 −1.98 1.29 −5.33 0 Week 28 26 −1.75 1.01 −4.67 −0.33 Week 52 37 −2.111.35 −6.33 0.67 n—population size; stddev—standard deviation;min—minimum; and max—maximum

Among males, decreases in mean nocturnal voids from baseline to week 52were observed. A summary of the changes from baseline to week 52 ispresented for all eligible male subjects in Tables G-I.

TABLE G Baseline at day 0 and changes from baseline of nocturnal voidsfor all eligible male subjects at the 25 μg dosage. n Mean Std Dev MinMax Day 0 48 3.26 1.24 2.00 6.33 Day 28 48 −0.76 1.18 −2.67 2.33 Week 835 −0.84 1.27 −3.33 2.67 Week 12 28 −0.90 1.19 −2.67 1.33 Week 20 20−1.25 1.13 −3.67 1.67 Week 28 40 −1.15 1.13 −3.67 1.00 Week 52 48 −1.131.28 −4.33 2.33 n—population size; stddev—standard deviation;min—minimum; and max—maximum

TABLE H Baseline at day 0 and changes from baseline of nocturnal voidsfor all eligible male subjects at the 50 μg dosage. n Mean Std Dev MinMax Day 0 45 3.59 1.25 2.00 7.00 Day 28 45 −1.16 1.23 −5.00 1.00 Week 832 −1.31 1.04 −3.67 1.33 Week 12 28 −1.30 1.11 −3.67 1.00 Week 20 30−1.73 1.13 −4.00 1.00 Week 28 25 −1.28 1.37 −5.00 1.00 Week 52 45 −1.691.58 −6.67 0.33 n—population size stddev—standard deviation;min—minimum; and max—maximum

TABLE I Baseline at day 0 and changes from baseline of nocturnal voidsfor all eligible male subjects at the 100 μg dosage. n Mean Std Dev MinMax Day 0 36 3.53 1.07 2.00 6.00 Day 28 36 −1.31 1.31 −3.67 4.33 Week 830 −1.52 0.90 −3.00 0.67 Week 12 19 −1.89 0.96 −3.33 0.33 Week 20 21−1.92 0.93 −3.33 −0.33 Week 28 21 −1.92 0.64 −3.500 −1.00 Week 52 36−2.12 0.89 −4.00 −0.33 n—population size stddev—standard deviation;min—minimum; and max—maximum

Tables J-L summarize the data for all subjects with or without anassessment at week 52.

TABLE J Baseline at day 0 and changes from baseline of nocturnal voidsfor all subjects at the 25 μg dosage. Std n Mean Dev Minimum Maximum Day0 158 3.38 1.35 2.00 8.67 Day 28 158 −0.96 1.12 −3.67 2.33 Week 100−1.31 1.16 −4.67 2.67 Week 12 85 −1.42 1.23 −5.00 2.00 Week 20 60 −1.611.16 −6.00 1.67 Week 28 87 −1.39 1.14 −4.33 1.33 Week 52 86 −1.41 1.26−4.67 2.33 n—population size; stddev—standard deviation; min—minimum;and max—maximum

TABLE K Baseline at day 0 and changes from baseline of nocturnal voidsfor all subjects at the 50 μg dosage. Std n Mean Dev Minimum Maximum Day0 157 3.39 1.05 2.00 7.33 Day 157 −1.10 1.19 −5.00 2.00 Week 92 −1.431.28 −6.33 2.33 Week 12 77 −1.51 1.16 −4.00 1.33 Week 20 64 −1.71 1.16−4.00 1.00 Week 28 61 −1.55 1.28 −5.00 1.67 Week 52 76 −1.80 1.31 −6.670.33 n—population size; stddev—standard deviation; min—minimum; andmax—maximum

TABLE L Baseline at day 0 and changes from baseline of nocturnal voidsfor all subjects at the 100 μg dosage. Std n Mean Dev Minimum MaximumDay 0 160 3.22 1.06 2.00 7.33 Day 28 160 −1.31 1.23 −5.00 4.33 Week 8104 −1.47 1.08 −5.00 0.67 Week 12 81 −1.73 1.04 −5.00 0.33 Week 20 64−1.86 1.08 −5.33 0 Week 61 −1.80 0.90 −4.67 0.67 Week 52 73 −2.11 1.14−6.33 0.67 n—population size; stddev—standard deviation; min—minimum;and max—maximum

Secondary Efficacy Endpoints

The secondary efficacy variables were changes from baseline in durationof initial period of undisturbed sleep, duration of total sleep time,and changes in nocturnal urine volume. As noted, the additionalsecondary efficacy variables data collected (i.e., global (overall)scores of the NQoL, PSQI, and SF-12v2, and scores of the ICIQ-N) are notpresented herein.

Duration of Initial Period of Undisturbed Sleep

The most pernicious effect of nocturia is not excessive voiding per se,but its impact on sleep quality and subsequent daytime function as aconsequence of sleep disruption. The duration of the initial period ofundisturbed sleep increased from baseline to Day 28 in all treatmentgroups, with greater increases observed with increasing dose ofdesmopressin. Mean increases in initial sleep duration were 83, 85, and107 minutes in the 25 μg, 50 μg, and 100 μg groups, respectively.Subjects treated with 25 μg and 50 μg desmopressin had a median increasein their initial period of sleep of approximately 1 hour while subjectstreated with the 100 μg dose had a median increase in initial sleepduration of approximately 1½ hours. The 95% confidence intervals for themean difference from placebo in change from baseline did not includezero for the 25 μg, 50 μg, and 100 μg groups, indicating statisticallysignificant treatment group differences.

A summary of changes from baseline to the final visit in initial periodof undisturbed sleep is presented for all groups (ITT population) inTable 8.

TABLE 8 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forall groups. Dose n mean stddev stderr min median max Placebo 126 39 89 8−273 42 386 10 ug 126 51 111 10 −317 51 457 25 ug 121 83 106 10 −104 62413 50 ug 123 85 109 10 −233 63 453 100 ug  121 107 116 11 −166 96 399Total 617 72 109 4 −317 60 457 n—population size; stddev—standarddeviation; stderr—standard error; min—minimum; and max—maximum

Although not statistically significant, an increase in the initialperiod of undisturbed sleep is evident for the 10 μg group as comparedto placebo based on median values identified in Table 8 for all groups.For example, the 10 μg group exhibited a median increase of 51 minutescompared to baseline before treatment. The placebo exhibited only amedian increase of 42 minutes compared to baseline. Taking intoconsideration a 5% range from the median increase for the 10 μg group,increases in an initial period of undisturbed sleep range from 48minutes to 54 minutes compared to baseline before treatment.

A summary of changes from baseline to the final visit in initial periodof undisturbed sleep is presented for all females, females over 50 yearsof age, and females over 65 years of age (ITT population) in Tables 9,10 and 11.

TABLE 9 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forall females. Dose n mean stddev stderr min median max Placebo 49 37 9413 −168 12 386 10 ug 60 54 117 15 −317 46 457 25 ug 51 113 118 17 −70 95413 50 ug 61 98 125 16 −233 70 453 100 ug  57 114 130 17 −166 93 399Total 278 84 121 7 −317 63 457 n—population size; stddev—standarddeviation; stderr—standard error; min—minimum; and max—maximum

Although not statistically significant, an increase in the initialperiod of undisturbed sleep is evident for the 10 μg and 25 μg groups ascompared to placebo based on median values identified in Table 9 for allfemale patients. For example, the 10 μg group exhibited a medianincrease of 46 minutes and the 25 μg group exhibited a median increaseof 95 minutes compared to baseline before treatment. The placeboexhibited only a median increase of 12 minutes compared to baseline.Taking into consideration a 20% range from the median increase for the10 μg and 25 μg groups, increases in an initial period of undisturbedsleep ranges from 37 minutes to 114 minutes, such as from 37 minutes to55 minutes for the 10 μg group and from 76 minutes to 114 minutes forthe 25 μg group compared to baseline for all females.

TABLE 10 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forfemales over 50 years of age. Dose n mean stddev stderr min median maxPlacebo 38 25 77 13 −168 11 168 10 ug 40 33 112 18 −317 27 293 25 ug 39122 123 20 −70 96 413 50 ug 48 83 126 18 −233 63 453 100 ug  42 108 12920 −166 89 330 Total 207 75 121 8 −317 54 453 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Although not statistically significant, an increase in the initialperiod of undisturbed sleep is evident for the 10 μg and 25 μg groups ascompared to placebo based on median values identified in Table 10 forfemale patients over 50 years of age. For example, the 10 μg groupexhibited a median increase of 27 minutes and the 25 μg group exhibiteda median increase of 96 minutes compared to baseline before treatment.The placebo exhibited only a median increase of 11 minutes compared tobaseline. Taking into consideration a 20% range from the median increasefor the 10 μg and 25 μg groups, increases in an initial period ofundisturbed sleep ranges from 22 minutes to 115 minutes, such as from 22minutes to 32 minutes for the 10 μg group and from 77 minutes to 115minutes for the 25 μg group, compared to baseline before treatment forfemales over 50 years of age.

TABLE 11 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forfemales over 65 years of age. Dose n mean stddev stderr min median maxPlacebo 19 50 60 14 −50 52 168 10 ug 18 18 125 29 −317 46 243 25 ug 15131 126 32 −70 113 413 50 ug 19 42 131 30 −233 30 288 100 ug  21 81 11926 −118 70 275 Total 92 62 118 12 −317 53 413 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Although not statistically significant, an increase in the initialperiod of undisturbed sleep is evident for the 25 μg group as comparedto placebo based on median values identified in Table 11 for femalepatients over 65 years of age. For example, the 25 μg group exhibited amedian increase of 113 minutes compared to baseline before treatment.The placebo exhibited only a median increase of 52 minutes compared tobaseline. Taking into consideration a 20% range from the median increasefor the 25 μg group, increases in an initial period of undisturbed sleeprange from 90 minutes to 136 minutes, such as from 102 minutes to 124minutes, compared to baseline before treatment for females over 65 yearsof age.

A summary of changes from baseline to the final visit in initial periodof undisturbed sleep is presented for all males and all males withmonitoring (ITT population) in Tables 12 and 13.

TABLE 12 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forall males. Dose n mean stddev stderr min median max Placebo 77 40 86 10−273 47 285 10 ug 66 48 107 13 −158 56 370 25 ug 70 61 90 11 −104 55 25950 ug 62 72 90 11 −165 55 292 100 ug  64 100 103 13 −152 101 363 Total339 63 97 5 −273 58 370 n—population size; stddev—standard deviation;stderr—standard error; min—minimum; and max—maximum

TABLE 13 Change from baseline to final visit (Day 28) in duration ofinitial period of undisturbed sleep (ITT analysis dataset in Part I) forall males with monitoring. Dose n mean stddev stderr min median maxPlacebo 70 44 85 10 −273 48 285 10 ug 60 54 107 14 −145 59 370 25 ug 6257 87 11 −104 54 259 50 ug 45 64 89 13 −165 59 291 100 ug  52 108 103 14−152 116 363 Total 289 64 96 6 −273 58 370 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Duration of Total Sleep Time

Total sleep time increased in all treatment groups in Part I; however,no pattern was observed by dose of desmopressin. Based on F-tests ofeffects, computed overall sleep duration and reported overall sleepduration were statistically significant predictors of change frombaseline to Day 28 in total sleep time (p<0.0001).

A summary of change from baseline to Day 28 in total sleep time ispresented by treatment group in Table 14.

TABLE 14 Change from baseline to final visit (Day 28) in total sleeptime (Part I). Total Sleep Time (min) Placebo 10 μg 25 μg 50 μg 100 μg(N = 156) (N = 155) (N = 152) (N = 148) (N = 146) Calculated Sleep (N =156) (N = 155) (N = 152) (N = 148) (N = 146) Time Baseline Mean (SD) 399(97.0)  397 (92.2)   397 (90.3)  404 (95.8)  414 (85.0) Median 410  402   412   415   418   Minimum,  (15, 732)  (135, 720)  (95, 577)  (20,577)  (72, 638) maximum Change from (N = 138) (N = 137) (N = 142) (N =138) (N = 133) Baseline Mean (SD) 31.4 (89.22) 9.7 (91.40) 19.7 (71.67)24.2 (79.60)   9.7 (77.33) Median 19.5 10.0 15.3 14.2 12.0 Minimum,(−167, 420) (−332, 282) (−191, 318) (−235, 218) (−300, 227) maximumReported Sleep (N = 156) (N = 155) (N = 152) (N = 148) (N = 146) TimeBaseline Mean (SD) 403 (83.7)  411 (72.8)   401 (77.8)  403 (83.7)  413(81.3) Median 408   400   410   409   410   Minimum,  (135, 625)  (190,613)  (77, 555)  (100, 580)  (100, 674) maximum Change from (N = 139) (N= 137) (N = 141) (N = 138) (N = 133) Baseline Mean (SD) 24.6 (80.66) 7.8(58.55) 15.9 (53.92) 24.9 (72.21)  19.0 (68.94) Median 20.3 10.0 10.020.0 20.0 Minimum, (−135, 525) (−130, 163) (−113, 228) (−168, 293)(−160, 197) maximum

Change in Urine Volume

Pharmacodynamic studies indicate that desmopressin has a very pronouncedantidiuretic effect. Nocturnal urine volume decreased in all treatmentgroups, with greater decreases observed with increasing desmopressindose. For change from baseline to Day 28 in nocturnal urine volume,based on F-tests of effects, treatment (p<0.0001), age (p=0.0067), andbaseline nocturnal urine volume (p<0.0001) were statisticallysignificant predictors for change from baseline. The 95% confidenceintervals for the mean difference from placebo in change from baselinedid not include zero for the 25 μg, 50 μg, and 100 μg groups, indicatingstatistically significant treatment group differences.

Similarly, total urine volume, which included both day and nocturnalvoids, decreased in all treatment groups, with greater decreasesobserved with increasing desmopressin dose. In the 50 μg group, a slightmean increase in urine output occurred during the day and, as a result,the nocturnal mean urine reduction was greater than the total mean urinereduction.

As shown in FIG. 3, the majority of the decrease in total urine volumewas a decrease in nocturnal volume. The decreases in nocturnal urinevolume for the 25 μg, 50 μg, and 100 μg groups were statisticallysignificant.

A summary of changes from baseline to the final visit in of nocturnalurine volume is presented for all groups (ITT population) in Table 15.

TABLE 15 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for all groups. Dose n meanstddev stderr min median max Placebo 140 −109 246 21 −817 −94 800 10 ug137 −164 277 24 −983 −150 568 25 ug 144 −224 264 22 −1,084 −233 567 50ug 138 −272 296 25 −1,017 −233 717 100 ug  135 −312 275 24 −1,238 −283408 Total 694 −216 281 11 −1,238 −200 800 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Although not statistically significant, a decrease in nocturnal urinevolume is evident for the 10 μg group as compared to placebo based onmedian decreases identified in Table 15 for all groups. For example, the10 μg group exhibited a median value decrease of 150 ml compared tobaseline before treatment. The placebo exhibited only a median decreaseof 94 ml compared to baseline. Taking into consideration a 20% rangefrom the median decrease for the 10 μg group, decreases in nocturnalurine volume include at least 120 ml and for example, range from 120 mlto 180 ml, compared to baseline before treatment for all groups.

A summary of changes from baseline to the final visit of nocturnal urinevolume is presented for all females, females over 50 years of age, andfemales over 65 years of age (ITT population) in Tables 16, 17 and 18.

TABLE 16 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for all females. Dose n meanstddev stderr min median max Placebo 60 −86 278 36 −817 −56 800 10 ug 66−207 292 36 −983 −179 538 25 ug 61 −307 276 35 −1,084 −298 292 50 ug 66−257 282 35 −1,017 −204 717 100 ug  60 −321 239 31 −933 −283 25 Total313 −236 285 16 −1,084 −217 800 n—population size; stddev—standarddeviation; stderr—standard error; min—minimum; and max—maximum

Although not statistically significant, a decrease in nocturnal urinevolume is evident for the 10 μg and 25 μg groups as compared to placebobased on median decreases identified in Table 16 for all females. Forexample, the 10 μg group exhibited a median decrease of 179 ml and the25 μg group exhibited a median decrease of 298 ml compared to baselinebefore treatment. The placebo exhibited only a median decrease of 56 mlcompared to baseline. Taking into consideration a 20% range from themedian decreases for the 10 μg and 25 μg groups, decreases in nocturnalurine volume include at least 143 ml and for example, range from 143 mlto 358 ml, such as from 143 ml to 215 ml for the 10 μg group and from238 ml to 358 ml for the 25 μg group, compared to baseline beforetreatment for all females.

TABLE 17 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for females over 50 years ofage. Dose n mean stddev stderr min median max Placebo 44 −102 242 36−817 −56 268 10 ug 45 −197 319 48 −983 −150 538 25 ug 46 −356 281 41−1,084 −383 292 50 ug 52 −249 289 40 −1,017 −196 717 100 ug  45 −317 25238 −933 −275 25 Total 232 −245 290 19 −1,084 −217 717 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Although not statistically significant, a decrease in nocturnal urinevolume is evident for the 10 μg and 25 μg groups as compared to placebobased on median decreases identified in Table 17 for females over 50years of age. For example, the 10 μg group exhibited a median decreaseof 150 ml and the 25 μg group exhibited a median decrease of 383 mlcompared to baseline before treatment. The placebo exhibited a mediandecrease of 56 ml compared to baseline. Taking into consideration a 20%range from the median decreases for the 10 μg and 25 μg groups,decreases in nocturnal urine volume include at least 120 ml and forexample, range from 120 ml to 460 ml, such as from 120 ml to 180 ml forthe 10 μg group and from 306 ml to 460 ml for the 25 μg group, comparedto baseline before treatment for females over 50 years of age.

TABLE 18 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for females over 65 years ofage. Dose n mean stddev stderr min median max Placebo 20 −90 170 38 −557−47 133 10 ug 22 −91 302 64 −742 −54 538 25 ug 19 −372 270 62 −867 −38325 50 ug 20 −208 323 72 −703 −203 717 100 ug  23 −323 261 54 −817 −28525 Total 104 −216 290 28 −867 −171 717 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

Although not statistically significant, a decrease in nocturnal urinevolume is evident for the 25 μg group as compared to placebo based onmedian decreases identified in Table 18 for females over 65 years ofage. For example, the 25 μg group exhibited a median decrease of 383 mlcompared to the placebo median decrease of 47 ml compared to baselinebefore treatment. Taking into consideration a 20% range from the mediandecrease for the 25 μg group, decreases in nocturnal urine volumeinclude at least 211 ml and for example, range from 238 ml to 290 ml,compared to baseline before treatment for females over 65 years of age.

A summary of changes from baseline to the final visit of nocturnal urinevolume is presented for all males and all males with monitoring (ITTpopulation) in Tables 19 and 20.

TABLE 19 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for all males. Dose n meanstddev stderr min median max Placebo 80 −125 219 25 −727 −111 583 10 ug71 −125 257 30 −750 −117 568 25 ug 83 −162 238 26 −873 −200 567 50 ug 72−286 309 36 −984 −246 422 100 ug  75 −306 302 35 −1,238 −270 408 Total381 −199 276 14 −1,238 −192 583 n—population size; stddev—standarddeviation; stderr—standard error; min—minimum; and max—maximum

TABLE 20 Change from baseline to final visit (Day 28) of nocturnal urinevolume (ITT analysis dataset in Part I) for all males with monitoring.Dose n mean stddev stderr min median max Placebo 72 −128 229 27 −727−111 583 10 ug 63 −122 269 34 −750 −83 568 25 ug 72 −146 219 26 −608−167 567 50 ug 50 −286 313 44 −984 −235 357 100 ug  60 −296 275 36 −867−264 408 Total 317 −188 268 15 −984 −183 583 n—population size;stddev—standard deviation; stderr—standard error; min—minimum; andmax—maximum

From Table 20, a decrease in nocturnal urine volume is evident for the100 μg group as compared to placebo based on median decreases frombaseline. For example, the 100 μg group exhibited a median decrease of264 ml compared to baseline before treatment. The placebo exhibited onlya median decrease of 111 ml compared to baseline. Taking intoconsideration a 20% range from the median decrease for the 100 μg group,decreases in nocturnal urine volume include at least 211 ml and forexample, range from 211 ml to 317 ml, such as from 238 ml to 290 ml,compared to baseline before treatment for males with monitoring.

The differences among males and females in the change in nocturnal urinevolume is illustrated in FIG. 4. In FIG. 4, the mean observed (fullline) and predicted (broken line) change in nocturnal urine volumedemonstrate the greater sensitivity to lower doses (i.e., 10 μg and 25μg groups) in females than males. The side-by-side comparison in FIG. 4highlights the gender and dose differences without the requirement ofstatistical significance.

Statistical/Analytical Issues—Handling of Dropouts or Missing Data

Missing values concerning number of nocturnal voids at Day 8, Day 15,Day 22, and Day 28 in Part I were imputed using last observation carriedforward (LOCF). Missing values concerning sleep disturbance and urinevolume (for average 24-hour urine volume and average nocturnal urinevolume) were not imputed.

Drug Dose, Drug Concentration and Relationships to Response

Four doses of desmopressin (10 μg, 25 μg, 50 μg, and 100 μg) wereincluded in this study. Both the primary endpoint of the number ofnocturnal voids generally demonstrated an increase in efficacy withincreasing dose of desmopressin. An additional analysis of the primaryefficacy endpoint was performed by gender and demonstrated genderdifferences in response. Among females, efficacy was demonstrated forthe 25 μg, 50 μg, and 100 μg doses of desmopressin for the primaryendpoint. Among males, the 100 μg desmopressin dose was superior toplacebo for the primary endpoint. Based on these gender differences, theMED for females is 25 μg and for males is 100 μg.

Efficacy Conclusions

Four doses of desmopressin (10 μg, 25 μg, 50 μg, and 100 μg) werecompared to placebo in this study for the primary endpoint in Part I:change in the mean number of nocturnal voids from baseline to finalvisit (Day 28).

The mean number of nocturnal voids decreased from baseline to Day 28 inall treatment groups, with greater decreases observed with increasingdose of desmopressin. The reduction in mean number of nocturnal voids,compared to placebo, was statistically significant for the 100 μg and 50μg groups. The trend of greater decreases in mean number of nocturnalvoids with increasing dose of desmopressin was evident in subjectsstratified by age (<65 years, ≥65 years) and in subjects with nocturnalpolyuria. Too few subjects did not have nocturnal polyuria to makemeaningful comparisons. The reduction in mean number of nocturnal voids,compared to placebo, was statistically significant for the 100 μg groupfor all 4 stratification factors and for the 50 μg group for subjectswith nocturnal polyuria. When decreases in mean number of nocturnalvoids were examined by week of treatment, statistically significantdifferences, compared to placebo, were observed for the 25 μg, 50 μg,and 100 μg doses on Day 8 and Day 15 of treatment, with significantdifferences for the 2 higher doses also on Day 22 and Day 28.

An additional analysis of the primary efficacy endpoint was performed bygender, and a gender difference in response was observed. Among females,the reduction in mean number of nocturnal voids was statisticallysignificantly superior to placebo for the 100 μg, 50 μg, and 25 μggroups. Among males, statistically significant differences from placebowere observed for the primary endpoint for the 100 μg group. Based onthese gender differences, the MED for females is 25 μg and the MED formales is 100 μg.

Nocturnal urine volume, as well as total urine volume, decreased in alltreatment groups, with greater decreases observed with increasingdesmopressin dose. Based on 95% confidence intervals that did notinclude zero, the decreases in nocturnal urine volume for the 25 μg, 50μg, and 100 μg groups were statistically significant.

The secondary efficacy endpoint of change from baseline to final visit(Day 28) in duration of initial period of undisturbed sleep alsodemonstrated greater increases with increasing dose of desmopressin.Subjects treated with 25 μg and 50 μg had a median increase in theirinitial period of sleep of approximately 1 hour while subjects treatedwith the 100 μg dose had a median increase in initial sleep duration ofapproximately 1½ hours; the 95% confidence intervals for the meandifference from placebo indicated statistically significant differencesfor the 25 μg, 50 μg, and 100 μg groups.

In summary, the efficacy of 100 μg desmopressin was demonstratedsuperior to placebo for the primary endpoint overall; for the primaryendpoint, among males and among females; proportions of subjectswith >50% and >75% reductions in the mean number of nocturnal voids;change from baseline to final visit (Day 28) in duration of the initialperiod of undisturbed sleep; and reductions in nocturnal urine volume.The efficacy of 50 μg desmopressin was superior to placebo for changefrom baseline to Day 28 in the mean number of nocturnal voids; for theprimary endpoint among females; duration of the initial period ofundisturbed sleep; and reductions in nocturnal urine volume. Inaddition, numerical superiority was observed for 50 μg desmopressincompared to placebo for the proportion of subjects with >33% reductions(53% vs. 47%), >50% reductions (28% vs. 20%), and >75% reductions (10%vs. 5%) in the mean number of nocturnal voids on Day 28. The 25 μg dosewas superior to placebo for the primary endpoint among females; inreducing the mean number of nocturnal voids; change from baseline to Day28 in duration of the initial period of undisturbed sleep; andreductions in nocturnal urine volume. The 10 μg dose did not demonstratestatistically superiority over placebo for the primary or secondaryefficacy endpoint. A gender difference in response was observed. For theprimary endpoint, superiority to placebo was demonstrated for the 25 μg,50 μg, and 100 μg doses among females and for the 100 μg dose amongmales.

Results of Study CS29 demonstrated that the 100 μg dose was clearlyefficacious, while the 10 μg dose can be considered subtherapeutic forthe primary efficacy parameter for the overall study population. Basedon the observed gender differences, the MED for females is 25 μg and theMED for males is 100 μg.

At 1 year, the mean decrease in nocturnal voids was 1.4, 1.77, and 2.11(for 25 μg, 50 μg, and 100 μg, respectively) based on all eligiblesubjects.

Adverse Events Leading to Discontinuation: Hyponatraemia and SerumSodium Monitoring

The reported event of hyponatraemia, defined as serum sodium <130mmol/L, was an adverse event of special interest. A total of 34 (4%)subjects developed hyponatraemia during Part I. There was essentially nodifference in the occurrence of hyponatraemia between placebo and the 10μg and 25 μg groups; however, the incidence of serum sodium <130 mmol/Lrose from 1.3% in the 25 μg group to 7.0% in the 50 μg group and to11.3% in the 100 μg group. Hyponatraemia tended to occur early intreatment, usually during the first week, and was more common insubjects 65 years of age.

Since hyponatraemia is a potentially serious adverse event associatedwith daily doses of desmopressin, serum sodium was monitored throughoutthe study in all subjects. Based on the results of Study CS29, thefollowing sodium monitoring criteria were applied to the CS29 data.

In subjects below 50 years of age:

Baseline serum sodium level ≥135 mmol/L.

In subjects 50 years of age and above:

Baseline serum sodium level ≥135 mmol/L

Day 4 serum sodium level ≥135 mmol/L

Day 28 serum sodium level ≥135 mmol/L.

Subjects who did not meet these criteria would be removed. Withoutmonitoring, serum sodium levels below 125 mmol/L occurred in 3 subjectseach in the 50 μg and 100 μg groups on Day 4 and 1 subject in each ofthese groups on Day 8. It should be remembered that serum sodiummonitoring occurred the day after the evening dose of study drug.

Based on these findings, serum sodium monitoring at Day 4 and Day 28 isrecommended in males older than 65 years of age at 100 μg. The serumsodium levels at Day 4 and Day 28 should be ≥135 mmol/L. In males below65 years of age who are treated at 100 μg, no further monitoring appearsto be warranted. In female subjects who are treated at 25 μg, no furthermonitoring appears to be warranted.

Dosing

Results of Study CS29 demonstrated that the 10 μg dose was considered asubtherapeutic dose for the primary efficacy parameters when looking atthe overall population. While the 100 μg dose was clearly efficacious,the risk of hyponatraemia was greater than with the lower doses ofdesmopressin. Although not as effective as the 100 μg dose, thebenefit:risk ratio favored the 25 μg and 50 μg doses. The 25 μg dose wasclearly less likely to cause hyponatraemia than the 50 μg and 100 μgdoses and was statistically significantly superior to placebo in theprimary efficacy endpoint among females. Among males, the 100 μgdesmopressin dose was statistically significantly superior to placebofor the primary endpoint. Based on these gender differences, the MED forfemales is 25 μg and the MED for males is 100 μg.

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Those skilled in the art will recognize, or be able to ascertain, usingno more than routine experimentation, numerous equivalents to thespecific embodiments described herein. Such equivalents are intended tobe encompassed in the scope of the following claims.

What is claimed is:
 1. A method of further reducing nocturnal voids in amale patient in need thereof comprising: measuring the patient's serumsodium level; administering to the patient, with a serum sodium level ofat least 130 mmol/L, prior to bedtime an orodispersible dose ofdesmopressin chosen from 25 μg, 50 μg, and 100 μg over a first treatmentperiod of about 28 days, wherein the dose is taken from 0.8 to 3 hoursprior to the patient's bedtime and once daily; measuring the patient'sserum sodium level after the first treatment period; and continuing toadminister the orodisperible dose of desmopressin prior to bedtime overa second contiguous treatment period of at least 28 days to about 1 yearif the male patient has a serum sodium level of at least 130 mmol/L,wherein the nocturnal voids over the second treatment period are furtherreduced in view of the reduction in the nocturnal voids over the firsttreatment period and wherein the reduction in the nocturnal voids overthe first treatment period is determined based on the patient'snocturnal voids before administration of the orodispersible dose ofdesmopressin for the first treatment period.
 2. The method according toclaim 1, wherein the dose of desmopressin free base is supplied in theform of the acetate salt of desmopressin.
 3. The method according toclaim 1, wherein the orodispersible dose of desmopressin is a dosageform comprising desmopressin acetate, gelatin, mannitol, and citricacid.
 4. The method according to claim 1, wherein the patient in needthereof has nocturia or nocturnal polyuria.
 5. The method according toclaim 1, wherein the reduction in nocturnal voids ranges from about onenocturnal void to about two nocturnal voids compared to the patient'snocturnal voids before administration of the dose.
 6. The methodaccording to claim 1, wherein the second contiguous treatment periodranges from about 8 weeks to about 1 year.
 7. The method according toclaim 1, wherein the second contiguous period is selected from about 8weeks, about 12 weeks, about 20 weeks, about 28 weeks, and about 52weeks.
 8. The method according to claim 7, wherein the second contiguousperiod is about 8 weeks.
 9. The method according to claim 7, wherein thesecond contiguous period is about 20 weeks.
 10. The method according toclaim 7, wherein the second contiguous period is about 52 weeks.
 11. Themethod according to claim 1, wherein the second contiguous treatmentperiod is about 1 year.
 12. The method according to claim 1, wherein thedose is taken without water.
 13. The method according to claim 1,wherein the dose is taken approximately 1 hour prior to the patient'sbedtime.